#ifndef ALIFMDRECONSTRUCTOR_H
#define ALIFMDRECONSTRUCTOR_H
-// -*- mode: c++ -*-
//
// Copyright(c) 1998-1999, ALICE Experiment at CERN, All rights
// reserved.
//
//-- Authors: Evgeny Karpechev (INR) and Alla Maevskaia (INR)
// Latest changes by Christian Holm Christensen <cholm@nbi.dk>
-/*
- Reconstruct nember of particles in given group of pads for given
- FMDvolume determine by numberOfVolume ,
- numberOfMinSector,numberOfMaxSector, numberOfMinRing,
- numberOfMaxRing Reconstruction method choose dependence on number
- of empty pads
- */
/* $Id$ */
+/** @file AliFMDReconstructor.h
+ @author Christian Holm Christensen <cholm@nbi.dk>
+ @date Mon Mar 27 12:47:09 2006
+ @brief FMD reconstruction
+*/
-#include <AliReconstructor.h>
-#include <AliFMDMap.h>
+//____________________________________________________________________
+// Header guards in the header files speeds up the compilation
+// considerably. Please leave them in.
+#ifndef ALIRECONSTRUCTOR_H
+# include <AliReconstructor.h>
+#endif
+#include "AliLog.h"
//____________________________________________________________________
+class TTree;
class TClonesArray;
-class AliFMD;
-class AliLoader;
-class AliRunLoader;
class AliFMDDigit;
class AliRawReader;
-typedef AliFMDMap<UShort_t> AliFMDAdcMap;
+class AliESDEvent;
+class AliESDFMD;
+class TH1;
+/** @defgroup FMD_rec Reconstruction */
//____________________________________________________________________
+/**
+ * @brief This is a class that reconstructs AliFMDRecPoint objects
+ * from of Digits.
+ *
+ * This class reads either digits from a TClonesArray or raw data
+ * from a DDL file (or similar), and applies calibrations to get
+ * psuedo-inclusive multiplicities per strip.
+ *
+ * @ingroup FMD_rec
+ */
class AliFMDReconstructor: public AliReconstructor
{
-protected:
- mutable AliFMDAdcMap fAdcs;
- mutable AliRunLoader* fRunLoader;
- mutable AliLoader* fFMDLoader;
- mutable TClonesArray* fParticles;
- mutable AliFMD* fFMD;
-
- Float_t fDeltaEta;
- Float_t fDeltaPhi;
- UShort_t fThreshold;
- Float_t fPedestal;
- Float_t fPedestalWidth;
- mutable Int_t fEmptyStrips;
- mutable Int_t fTotalStrips;
-
- enum {
- kMaxDetectors = 3,
- kMaxRings = 2,
- kMaxSectors = 20,
- kMaxStrips = 512
- };
-
public:
+ /**
+ * CTOR
+ */
AliFMDReconstructor();
- virtual ~AliFMDReconstructor() {}
+ /**
+ * DTOR
+ */
+ virtual ~AliFMDReconstructor();
+
+ /**
+ * Initialize the reconstructor. Here, we initialize the geometry
+ * manager, and finds the local to global transformations from the
+ * geometry. The calibration parameter manager is also
+ * initialized (meaning that the calibration parameters is read
+ * from CDB).
+ */
+ virtual void Init();
+ /**
+ * Flag that we can convert raw data into digits.
+ *
+ * @return always @c true
+ */
+ virtual Bool_t HasDigitConversion() const { return kTRUE; }
+ /**
+ * Convert raw data read from the AliRawReader @a reader into
+ * digits. This is done using AliFMDRawReader and
+ * AliFMDAltroReader. The digits are put in the passed TTree @a
+ * digitsTree.
+ *
+ * @param reader Raw reader.
+ * @param digitsTree Tree to store read digits in.
+ */
+ virtual void ConvertDigits(AliRawReader* reader, TTree* digitsTree) const;
+ /**
+ * Reconstruct one event from the digits passed in @a digitsTree.
+ * The member function creates AliFMDRecPoint objects and stores
+ * them on the output tree @a clusterTree. An FMD ESD object is
+ * created in parallel.
+ *
+ * @param digitsTree Tree holding the digits of this event
+ * @param clusterTree Tree to store AliFMDRecPoint objects in.
+ */
+ virtual void Reconstruct(TTree* digitsTree, TTree* clusterTree) const;
+ /**
+ * Not used
+ * @todo Implement this, such that we'll reconstruct directly from
+ * the read ADC values rather than going via an intermedant
+ * TClonesArray of AliFMDDigits
+ */
+ virtual void Reconstruct(AliRawReader *, TTree*) const;
+ /**
+ * Put in the ESD data, the FMD ESD data. The object created by
+ * the Reconstruct member function is copied to the ESD object.
+ *
+ * @param digitsTree Tree of digits for this event - not used
+ * @param clusterTree Tree of reconstructed points for this event -
+ * not used.
+ * @param esd ESD object to store data in.
+ */
+ virtual void FillESD(TTree* digitsTree, TTree* clusterTree,
+ AliESDEvent* esd) const;
+ /**
+ * Forwards to above member function
+ */
+ virtual void FillESD(AliRawReader*, TTree* clusterTree,
+ AliESDEvent* esd) const;
- void SetDeltaEta(Float_t deta=.1) { fDeltaEta = deta; }
- void SetDeltaPhi(Float_t dphi=360) { fDeltaPhi = dphi; }
- void SetThreshold(UShort_t t=6) { fThreshold = t; }
- void SetPedestal(Float_t mean=10, Float_t width=1);
-
- virtual void Reconstruct(AliRunLoader* runLoader) const;
- virtual void Reconstruct(AliRunLoader* runLoader,
- AliRawReader* rawReader) const;
- virtual void FillESD(AliRunLoader* runLoader, AliESD* esd) const;
+ /**
+ * Create SDigits from raw data
+ *
+ * @param reader The raw reader
+ * @param sdigits Array to fill with AliFMDSDigit objects.
+ */
+ virtual void Digitize(AliRawReader* reader,
+ TClonesArray* sdigits) const;
+ /**
+ * Not used
+ */
+ virtual void SetESD(AliESDEvent* esd) { fESD = esd; }
+ /**
+ * Set the noise factor
+ *
+ * @param f Factor to use
+ */
+ virtual void SetNoiseFactor(Float_t f=3) { fNoiseFactor = f; }
+ /**
+ * Set whether we should do angle correction or nor
+ *
+ * @param use If true, do angle correction
+ */
+ virtual void SetAngleCorrect(Bool_t use=kTRUE) { fAngleCorrect = use; }
+ /**
+ * Set whether we want to do diagnostics. If this is enabled, a
+ * file named @c FMD.Diag.root will be made. It contains a set of
+ * histograms for each event, filed in separate directories in the
+ * file. The histograms are
+ * @verbatim
+ * diagStep1 Read ADC vs. Noise surpressed ADC
+ * diagStep2 Noise surpressed ADC vs. calculated Energy dep.
+ * diagStep3 Energy deposition vs. angle corrected Energy dep.
+ * diagStep4 Energy deposition vs. calculated multiplicity
+ * diagAll Read ADC vs. calculated multiplicity
+ * @endverbatim
+ *
+ * @param use If true, make the diagnostics file
+ */
+ void SetDiagnose(Bool_t use=kTRUE) { fDiagnostics = use; }
protected:
- virtual void ProcessEvent(Int_t event,
- AliRawReader* rawReader,
- TClonesArray* digits) const;
- virtual Bool_t ReadAdcs(TClonesArray* digits) const;
- virtual Bool_t ReadAdcs(AliRawReader* rawReader) const;
- virtual void ProcessDigit(AliFMDDigit* digit) const;
- virtual UShort_t SubtractPedestal(AliFMDDigit* digit) const;
- virtual void ReconstructFromCache(Float_t zVertex) const;
- ClassDef(AliFMDReconstructor, 0) // class for the FMD reconstruction
+ /**
+ * Copy CTOR
+ *
+ * @param other Object to copy from.
+ */
+ AliFMDReconstructor(const AliFMDReconstructor& other);
+ /**
+ * Assignment operator
+ *
+ * @param other Object to assign from
+ *
+ * @return reference to this object
+ */
+ AliFMDReconstructor& operator=(const AliFMDReconstructor& other);
+ /**
+ * Try to get the vertex from either ESD or generator header. Sets
+ * @c fCurrentVertex to the found Z posistion of the vertex (if
+ * found), and sets the flag @c fVertexType accordingly
+ *
+ * @param esd ESD structure to get Vz from
+ */
+ virtual void GetVertex(AliESDEvent* esd) const;
+ /**
+ * Process AliFMDDigit objects in @a digits. For each digit, find
+ * the psuedo-rapidity @f$ \eta@f$, azimuthal angle @f$ \varphi@f$,
+ * energy deposited @f$ E@f$, and psuedo-inclusive multiplicity @f$
+ * M@f$.
+ *
+ * @param digits Array of digits.
+ */
+ virtual void ProcessDigits(TClonesArray* digits) const;
+ /**
+ * Process a single digit
+ *
+ * @param digit Digiti to process
+ */
+ virtual void ProcessDigit(AliFMDDigit* digit) const;
+ /**
+ * Process the signal from a single strip.
+ *
+ * @param det Detector number
+ * @param rng Ring identifier
+ * @param sec Sector number
+ * @param str Strip number
+ * @param adc Number of ADC counts for this strip
+ */
+ virtual void ProcessSignal(UShort_t det,
+ Char_t rng,
+ UShort_t sec,
+ UShort_t str,
+ Short_t adc) const;
+ /**
+ * Process the signal from a single strip.
+ *
+ * @param sdigits Array to fill
+ * @param det Detector number
+ * @param rng Ring identifier
+ * @param sec Sector number
+ * @param str Strip number
+ * @param sam Sample number
+ * @param adc Number of ADC counts for this strip
+ */
+ virtual void DigitizeSignal(TClonesArray* sdigits,
+ UShort_t det,
+ Char_t rng,
+ UShort_t sec,
+ UShort_t str,
+ UShort_t sam,
+ Short_t adc) const;
+ /**
+ * Subtract the pedestal off the ADC counts.
+ *
+ * @param det Detector number
+ * @param rng Ring identifier
+ * @param sec Sector number
+ * @param str Strip number
+ * @param adc ADC counts
+ * @param noiseFactor If pedestal substracted pedestal is less then
+ * this times the noise, then consider this to be 0.
+ * @param zsEnabled Whether zero-suppression is on.
+ * @param zsNoiseFactor Noise factor used in on-line pedestal
+ * subtraction.
+ *
+ * @return The pedestal subtracted ADC counts (possibly 0), or @c
+ * USHRT_MAX in case of problems.
+ */
+ virtual UShort_t SubtractPedestal(UShort_t det,
+ Char_t rng,
+ UShort_t sec,
+ UShort_t str,
+ UShort_t adc,
+ Float_t noiseFactor,
+ Bool_t zsEnabled,
+ UShort_t zsNoiseFactor) const;
+ /**
+ * Substract pedestals from raw ADC in @a digit
+ *
+ * @param det Detector number
+ * @param rng Ring identifier
+ * @param sec Sector number
+ * @param str Strip number
+ * @param adc Number of ADC counts
+ *
+ * @return Pedestal subtracted ADC count.
+ */
+ virtual UShort_t SubtractPedestal(UShort_t det,
+ Char_t rng,
+ UShort_t sec,
+ UShort_t str,
+ Short_t adc) const;
+ /**
+ * Converts number of ADC counts to energy deposited. This is
+ * done by
+ * @f[
+ * E_i = A_i g_i
+ * @f]
+ * where @f$ A_i@f$ is the pedestal subtracted ADC counts, and @f$
+ * g_i@f$ is the gain for the @f$ i^{\mbox{th}}@f$ strip.
+ *
+ * @param det Detector number
+ * @param rng Ring identifier
+ * @param sec Sector number
+ * @param str Strip number
+ * @param eta Psuedo-rapidity of digit.
+ * @param count Pedestal subtracted ADC counts
+ *
+ * @return Energy deposited @f$ E_i@f$
+ */
+ virtual Float_t Adc2Energy(UShort_t det,
+ Char_t rng,
+ UShort_t sec,
+ UShort_t str,
+ UShort_t count) const;
+ /**
+ * Converts number of ADC counts to energy deposited. This is
+ * done by
+ * @f[
+ * E_i = A_i g_i
+ * @f]
+ * where @f$ A_i@f$ is the pedestal subtracted ADC counts, and @f$
+ * g_i@f$ is the gain for the @f$ i^{\mbox{th}}@f$ strip.
+ *
+ * @param det Detector number
+ * @param rng Ring identifier
+ * @param sec Sector number
+ * @param str Strip number
+ * @param eta Psuedo-rapidity of digit.
+ * @param count Pedestal subtracted ADC counts
+ *
+ * @return Energy deposited @f$ E_i@f$
+ */
+ virtual Float_t Adc2Energy(UShort_t det,
+ Char_t rng,
+ UShort_t sec,
+ UShort_t str,
+ Float_t eta,
+ UShort_t count) const;
+ /**
+ * Converts an energy signal to number of particles. In this
+ * implementation, it's done by
+ * @f[
+ * M_i = E_i / E_{\mbox{MIP}}
+ * @f]
+ * where @f$ E_i@f$ is the energy deposited, and
+ * @f$ E_{\mbox{MIP}}@f$ is the average energy deposited by a
+ * minimum ionizing particle
+ *
+ * @param det Detector number
+ * @param rng Ring identifier
+ * @param sec Sector number
+ * @param str Strip number
+ * @param eta On return, psuedo-rapidity @f$ \eta@f$
+ * @param phi On return, azimuthal angle @f$ \varphi@f$
+ * @param edep Energy deposited @f$ E_i@f$
+ *
+ * @return Psuedo-inclusive multiplicity @f$ M@f$
+ */
+ virtual Float_t Energy2Multiplicity(UShort_t det,
+ Char_t rng,
+ UShort_t sec,
+ UShort_t str,
+ Float_t edep) const;
+ /**
+ * Calculate the physical coordinates psuedo-rapidity @f$ \eta@f$,
+ * azimuthal angle @f$ \varphi@f$ of the strip corresponding to
+ * the digit @a digit. This is done by using the information
+ * obtained, and previously cached by AliFMDGeometry, from the
+ * TGeoManager.
+ *
+ * @param det Detector number
+ * @param rng Ring identifier
+ * @param sec Sector number
+ * @param str Strip number
+ * @param eta On return, psuedo-rapidity @f$ \eta@f$
+ * @param phi On return, azimuthal angle @f$ \varphi@f$
+ */
+ virtual void PhysicalCoordinates(UShort_t det,
+ Char_t rng,
+ UShort_t sec,
+ UShort_t str,
+ Float_t& eta,
+ Float_t& phi) const;
+
+ enum Vertex_t {
+ kNoVertex, // Got no vertex
+ kGenVertex, // Got generator vertex
+ kESDVertex // Got ESD vertex
+ };
+ mutable TClonesArray* fMult; // Cache of RecPoints
+ mutable Int_t fNMult; // Number of entries in fMult
+ mutable TTree* fTreeR; // Output tree
+ mutable Float_t fCurrentVertex; // Z-coordinate of primary vertex
+ mutable AliESDFMD* fESDObj; // ESD output object
+ Float_t fNoiseFactor; // Factor of noise to check
+ Bool_t fAngleCorrect; // Whether to angle correct
+ mutable Vertex_t fVertexType; // What kind of vertex we got
+ AliESDEvent* fESD; // ESD object(?)
+ Bool_t fDiagnostics; // Wheter to do diagnostics
+ TH1* fDiagStep1; // Diagnostics histogram
+ TH1* fDiagStep2; // Diagnostics histogram
+ TH1* fDiagStep3; // Diagnostics histogram
+ TH1* fDiagStep4; // Diagnostics histogram
+ TH1* fDiagAll; // Diagnostics histogram
+ mutable Bool_t fZS[3]; // Zero-suppredded?
+ mutable UShort_t fZSFactor[3]; // Noise factor for Zero-suppression
+private:
+
+ ClassDef(AliFMDReconstructor, 3) // class for the FMD reconstruction
};
#endif
//____________________________________________________________________
//
+// Local Variables:
+// mode: C++
+// End:
+//
// EOF
//